Chapter 20
Antarctic Navigation

Land navigation in Antarctica has undergone a dramatic change over the
past several years due to the increased availability of Global Positioning
System (GPS) coverage and equipment.

While GPS is a valuable resource to field parties, it should not be
relied upon as the sole method of navigation. There are several methods
to plot position and navigate in the event a GPS is unavailable. Magnetic
compasses, sun compasses, sextants, and dead reckoning are all valuable
tools to the Antarctic traveler, but they each have their drawbacks.

Prior to your field deployment, you should choose the navigational methods
that best suit your location and learn how to use them. You won't have
time to figure it out in the field -- you can't afford to be wrong while
you're learning on the job.

20.1 Global Positioning System

There are still some problems with using GPS in the field. Coverage
at the higher latitudes is limited to certain, yet predictable, hours
of the day. At times accuracy is diminished by the low incident angles
of the satellites to the horizon. In addition, parties using GPS have
reported interruption of service for as long as 72 hours at a time when
the system was down for maintenance. Before planning to use GPS, use the
software provided with your system to check availability of coverage at
your expected location. If GPS is a part of your work in the field, you
will likely have to plan your work day around the "windows" of satellite
coverage.

20.2 Magnetic Compasses

Magnetic compasses must be modified for use in polar latitudes by re-weighting
the needle. As the compass gets closer to the South Pole, the south-seeking
end of the needle is pulled downward toward the earth and will drag on
its enclosure unless the proper nonmagnetic counterweight (copper wire)
is added to the north-seeking end.

Field parties must be careful of localized magnetic variations. On Ross
Island, for example, magnetic compasses are unusable because there is
so much iron in the rock. Likewise, compasses are affected by the metal
in vehicles. Bearings must be taken well away from such disturbing influences.

Navigation with magnetic compass over long distances is difficult because
the magnetic variation (the difference between magnetic and true north)
is so high, and changes significantly over short distances. Field parties
may elect to travel by using a Grid North system (see the "Grid North"
section below), versus a Magnetic or True North system.

20.3 Grid North

Grid North is an artificially-convened reference direction which is
taken to be parallel to the Greenwich Meridian. The North/South Grid Lines
run parallel to each other and do not converge at the poles (see chart
on the following page).

* [See figure łNAV1˛]

By contrast, meridians of longitude converge so sharply near the poles
that expressing headings with respect to True North becomes impractical.

The VXE-6, as well as other agencies, circumvent this problem by using
Grid North's constant reference direction. This is not only practical
for the aviator, but can also greatly simplify matters for the land traveler
using a magnetic compass.

For locations south of the equator, the following rules apply:

Easterly Longitudes

Grid direction = True direction + Longitude of your camp

True direction = Grid direction - Longitude of your camp

Westerly Longitudes

Grid direction = True direction - Longitude of your camp

True direction = Grid direction + Longitude of your camp

Note: When giving a Field Weather Observation, wind direction must always
be given in relation to Grid North.

Sun compasses are an accurate way to determine bearings. Sextants (in
conjunction with an artificial horizon) are a good way to fix your position.
Both methods require an accurate chronometer and extensive knowledge on
how to use navigational tables to get good results.